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        <h1 class="margin-bottom">Neuropharmacology</h1>
        <span class="block">
          Further details on using mini-fUS for pharmacological studies, including dose-response investigations, tracking dynamic changes post-drug
          administration, and comparing effects of different compounds. Emphasize the ability to perform longitudinal studies in the same animals.
        </span>
      </article>
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    <section class="min-h-screen flex-cc applications-card-ul">
      <ul class="card-box nbn">
        <li class="card-item auto">
          <article>
            Content detailing rsFC applications, methodologies, example data, and relevant publications will be added here. Our system's ability to capture
            subtle, spontaneous fluctuations in neural activity across the entire brain in awake animals is a key advantage for these studies.
          </article>
        </li>
        <li class="card-item">
          <article>
            <img width="100%" :src="imgDefault" />
          </article>
        </li>
        <li class="card-item auto">
          <article>
            <p>2D connectivity matrices</p>
            <p class="margin-top margin-bottom">Seed-Based correlation mapping</p>
            <p>Functional connectivity in pathological models</p>
          </article>
        </li>
      </ul>
    </section>
    <section class="min-h-screen flex-cc applications-card-ul">
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        <li class="card-item">
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            <img width="100%" :src="imgDefault" />
          </article>
        </li>
        <li class="card-item auto">
          <article>
            <h3>2D Investigating connectivity in moving animals</h3>
            <p class="margin-top padding">
              While connectivity matrices are traditionally generated in anesthetized animals, a significant advancement involves employing the lightweight and
              durable Thunder's probe to acquire data in awake mice—whether freely moving or head-fixed—thereby eliminating the confounding effects of
              anesthesia.
            </p>
          </article>
        </li>
        <li class="card-item auto">
          <article>
            <h3>2D Investigating connectivity in moving animals</h3>
            <p class="margin-top padding">
              While connectivity matrices are traditionally generated in anesthetized animals, a significant advancement involves employing the lightweight and
              durable Thunder's probe to acquire data in awake mice—whether freely moving or head-fixed—thereby eliminating the confounding effects of
              anesthesia.
            </p>
          </article>
        </li>
      </ul>
    </section>
  </section>
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